RU2561717C2 - Electric connecting terminal - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is referred to an electric connecting terminal (1) with a body (2) of an insulating material and at least one spring-actuated clamp connecting element. The spring-actuated clamp connecting element comprises a locking spring (3) with a supporting arm (5), a spring arc (6) joining to it and a driving arm (7). The driving arm (7) has a notch (8) with a section (4) of a current-conducting busbar passing through it and which lower jumper (9) forms a place for clamping an electric wire (23) between the jumper (9) and the section (4) of the current-conducting busbar. A plate (16) comes forward and outside from the driving arm (7) in the direction opposite to the rear arc of the spring. Each spring-actuated clamp connecting element has an actuating rod (12), which if placed so that it may rotate in front of the clamping section of the driving arm (7) in the locking spring (3) by joining to the plate (16), and a support (18) oriented for superimposition to the plate (16).

EFFECT: development of a compact electric clamp with a low driving effort.

12 cl, 5 dwg

Description

The invention relates to an electrical connection clamp with a housing of insulating material and with at least one spring-clamping connecting element located in the housing of insulating material, and at least one spring-clamping connecting element contains a locking spring that has a supporting arm applied on the portion of the conductive bus, the rear arc of the spring adjacent to it, and the drive arm, and the drive arm in the portion of the clamp, bent in the direction of the portion of the conductive th bus has a recess made in the form of a window through which a portion of the tire passes and the lower cross member of which forms the clamping point for clamping the electric wire between the cross member and the portion of the current-carrying bus, and, moreover, the drive arm plate protrudes outward in the opposite direction to the rear arc of the spring .

Such electrical connection clamps with a drive arm for a spring clamp connection element are known in a multifaceted form.

DE 102008017738 A1 describes an electrical connection clamp with a locking spring, which can be opened by means of a drive arm rotatably disposed in a housing of insulating material. In this case, the drive lever is located above the locking spring and the contact surface extending from approximately the height of the support pin to the free end on the lower side of the drive lever and rests when the drive lever is rotated onto the back of the locking spring. Due to this, the locking back is pressed down and the locking spring is opened.

DE 202007001701 U1 discloses an electrical connection clamp with a twisted bending spring that has a recess through which the tire plate passes. The lower edge of the recess forms a clamping point for the electric wire with the busbar, which, through the inlet for the wire, passing through the recess, can be inserted into the housing of insulating material. Above the twisted bending spring, a drive lever is located that can be rotated, which loads the upper edge edge bounding the recess at the free end of the twisted bending spring. When the drive lever is turned, which acts on the end of the clamping arm, the clamping position opens.

DE 19802945 C2 discloses an electric clamp with a locking spring which is located on a conductive busbar. The protrusion of the material at the upper edge, made in the form of a window of the recess of the clamping arm of the clamping spring, is bent outward so that the protrusion of the material is a guide protrusion for the end of the drive tool. When a screwdriver is introduced as a drive tool in the direction of the length of the support arm of the clamping spring, the end of the tool falls onto this protrusion of the material, due to which the clamping arm of the clamping spring is gently pressed downward from the feed movement of the power tool with a soft movement to open the clamping point. Due to the fact that the end of the tool acts on the end of the protrusion of the material, the length of the lever arm increases.

Based on this, the object of the present invention is to provide an improved electrical clamp with a drive arm, which is compact and requires as little drive effort as possible.

The problem is solved by means of an electric connecting clamp of the type mentioned above due to the fact that each spring-clamping connecting element has a drive lever that is rotatably located in front of the clamping portion of the drive arm of the locking spring adjacent to the plate and the support oriented (when triggered) for overlay on the plate.

The drive lever is not located above the clamping spring, as this, in itself, is known from the prior art. The pivot bearing is located, rather, in front of the locking spring, adjacent to the plate extending from the drive arm forward from the rear spring arc. In this case, the drive lever with its support is located on the plate, so that the drive section, when the drive lever is rotated, is pressed down in the direction of the tire section. Thanks to the plate, the lever arm is increased and thereby the required lever force is reduced. The location of the support in front of the locking spring adjacent to the plate has the advantage that the connection clamp can be made very compact. In addition, the excessive load of the support journal of the drive arm is achieved by installing the drive arm adjacent to the plate in a housing of insulating material.

Preferably, if the plate extends in a common plane with the portion of the drive arm extending in the direction of the spring arc and adjacent to the plate, and the portion of the drive portion provided with a window-shaped recess is bent from this plane in the direction of the portion of the conductive busbar. Thus, the support of the drive arm during rotation continuously slides along the plane of application of the plate and the adjacent portion of the drive arm, without clinging to it. In addition, thanks to this, the lever arm is optimized with respect to the spring arc. This is valid, in particular, if the plate and the adjacent portion of the drive arm extend in the direction of the central region of the spring arc.

Further, it is preferable if the drive lever with support pins protruding on the sides, is rotatably located in the corresponding recesses of the housing of insulating material. Thus, the drive lever is stably maintained and guided without the possibility of folding.

For this, the drive arm must be molded in one piece from plastic. Thus, the drive arm can be manufactured economically and provide a stable shape. In this case, the drive lever has a lever arm and a support shaft partially enclosed on the lower side by a lever arm in the region of the drive end of the drive arm. The arm of the lever is, therefore, lapped on the support shaft, so that when triggered, the tipping moment acting on the arm of the lever is optimally converted into rotational movement of the support shaft. The ends of the support shaft protrude from the lateral surfaces of the lever arm to form support trunks protruding on the sides. In the bearing shaft, then, under the lever arm there is free space for receiving the locking spring plate. The upper wall of the free space in this case forms a support for the plate. Thus, the force of the drive lever in the region of the support shaft is transmitted to the locking spring plate. Due to this, the tilting moments acting on the support trunnions and the adjacent housing of the insulating material of the connecting clamp are kept as small as possible.

The plate support on the lower side of the drive arm extends preferably into a curved portion that extends from the free drive end of the drive arm to the upper side of the drive arm adjacent to the free drive end. Thus, when the drive arm is rotated, the plate and the adjacent portion of the drive arm slide over a curved portion with the least possible friction at the free drive end.

The electrical connection clamp can be, for example, a plug connector with a large number of spring-clamped connection elements. Moreover, each spring-clamping connecting element may have its own conductive bus. Preferably, if the conductive busbar on the side of the housing is made of insulating material, which is opposite to the lead-in hole for the wire in the housing of insulating material leading to the corresponding spring-clamping connecting element, has a plug connector for the mating portion of the plug connector. Thus, the individual wires can be connected to the respective spring-clamping connecting elements on one side of the connecting clamp. On the opposite side or at least the upper / lower side of the plug connector bent, the counterpart of the plug connector can then be inserted into the corresponding plug connectors to create a detachable electrical connection. It is also possible, however, for the plug to be formed as a solder connection for the printed circuit boards.

In another embodiment, the electrical connection clamp with a large number of spring-clamped connecting elements may have a common conductive bus for connecting many spring-clamped connecting elements. In this case, there are several sections of the conductive bus for the corresponding spring-clamping connecting elements on the common conductive bus. In this regard, it is also possible that the electrical connection clamp has two or more conductive busbars separated from each other, which respectively have one or more sections of the conductive bus bar for the respective spring-clamp connection elements.

The invention is explained below based on the attached drawings. Showing:

Figure 1 is a side view of a cross section of an electrical connecting clamp with a closed spring-clamping connecting element;

Figure 2 is a side view of the cross section of figure 1 with an open spring-clamping connecting element and an inserted electrical wire;

Figure 3 is a rear view in perspective of the drive lever of the connecting clamp of figure 1;

Figure 4 is a side perspective view of the drive arm of Figure 3;

FIG. 5 is a perspective view of the electrical connection clamp of FIG. 2.

Figure 1 allows you to recognize the electrical connection clamp 1 with the housing 2 made of insulating material. In the housing 2 of the insulating material formed spring-clamping connecting elements, each with a locking spring 3 and a portion of the conductive bus. The locking spring 3 in a known manner has a supporting arm 5, resting on a portion 4 of the conductive bus, which is adjacent to the arc 6 of the spring. From the spring arc 6, the drive arm 7 again passes in the opposite direction, so that the locking spring 3 in this region is curved in approximately U-shape. The drive arm 7 is bent in this case in the direction of the conductive busbar section 4 and the support arm 5 and has a recess in this area in the form of a window through which the conductive busbar section 4 passes and, optionally, also a part of the support arm 5. Under the conductive portion 4 the tire, a recess 8 in the form of a window is bounded by a cross member 9, which forms a clamping point for clamping an electric wire between the cross member 9 and the conductive bus section 4.

In order to achieve, as far as possible, the precise superposition of the electric wire on the conductive busbar section 4 with the smallest possible contact area for the electric wire, a bulge 10 is provided on the conductive busbar section 4, which adjoins the cross member 9 when not clamped, the clamping force of the locking spring 3 is concentrated, thus, on this bulge 10, whereby a high specific pressure is achieved.

An electric wire through the wire entry hole 11 on the front side of the housing 2 of insulating material is inserted into the housing of the insulating material and is conducted under the portion 4 of the conductive bus to be located between the portion of the conductive 4 bus and the cross member 9.

In order to be able to clamp such an electric wire, it is necessary to first actuate the locking spring 3 once, pressing the upper part of the drive arm 7 down in the direction of the portion 4 of the conductive busbar and the support arm 5. To do this, use the drive arm 12, which is located by the support pins on the support shaft 13 with the possibility of rotation in the insulating housing 2.

The drive lever 12 has a lever arm 14 with a free end 15, which can be gripped by the user to rotate the drive arm 12. Under the arm of the lever opposite to the free end 15, the support shaft 13 is formed together with the lever arm 14. Thus, the drive arm 12 is formed integrally, for example, from an insulating plastic material.

To increase the lever arm when the locking spring 3 is triggered, the plate 16 protrudes from the portion of the drive arm 7 adjacent to the spring arc 6, which is bent not in the direction of the conductive busbar section 4 and the supporting arm 5. Now, when the locking spring 3 is opened (for actuation) the drive lever 12 acts on this protruding plate, so that the lever arm between the point of action of the drive lever 12 on the locking spring 3 and the Central region of the arc 6 of the spring increases compared with the action of the locking th spring 3 on the drive arm 7 closer to the arc 6 of the spring in the area between the fold of the drive arm and the arc 6 of the spring.

The plate 16 is located in the free space 17 of the drive lever 12. The free space of the drive lever 12 is created by a recess in the support shaft 13, and the upper side of the free space serves as a support 18 for the plate 16.

You can see that the support 18 for the plate 16 on the lower side of the drive arm 12 passes into a curved section 19, which extends from the free end of the drive end of the drive arm 12 to the upper side of the drive arm 12, which is adjacent to the free drive end.

The free drive end thus lies opposite the free end 15 of the drive arm 12.

The presented housing 2 of insulating material is made of two parts. The locking spring 3 together with the portion 4 of the conductive bus is installed in the first part 2a of the housing 2 from an insulating material. After installing the drive arm 12, the housing 2 of the insulating material is completed by pushing and fixing the second part 2b. The pivot bearing for the drive arm 12 is implemented using the first and second parts 2a and 2b.

In the presented embodiment, the electrical connection clamp 1 is made in the form of a plug connector. In this case, each spring-clamping connecting element has its own current-carrying bus, which on the side opposite to the spring-clamping connecting element with a hole 11 for the input of the wire has a plug connector for receiving the mating part of the plug connector. The plug connector formed by the conductive busbar portion 4 may be surrounded by a guide and protective wall 21 of the insulating material of the housing to create a plug with a predetermined contour for receiving the mating portion of the plug connector.

Of course, it is also possible that the plug is bent at an angle and protrudes up or down. It is also possible that the plug 20 formed by the conductive busbar portion 4 is in the form of a solder pin or a solder plate to solder the connection clip to the printed circuit board. There is no guide and protective wall in this case.

The inspection and inspection hole 26 in the housing 2 made of insulating material makes it possible to access the end of the wire 22 so that it can be visually checked whether the end of the wire 22 is correctly and completely inserted. Additionally, through the inspection and inspection hole 26, you can check whether voltage is applied.

Figure 2 shows a cross-sectional side view of the connecting clip 1 according to Figure 1 with the locking spring 3 actuated. It is clear that the drive lever 12 is rotated upward clockwise. The curved portion 19 is supported by the upper side of the drive arm 12 adjacent to the free drive end, now on the plate 16, which protrudes forward from the drive arm 7. Due to this, the locking spring 3 is opened so that the cross member 9 is brought down from the wire entry hole. The insulation-free end 22 of the electric wire 23 can thus be guided through a recess 8 in the form of a window for a portion 4 of the conductive bus. When the drive arm 12 is rotated backward, the locking spring 3 is released, so that the insulation end 22 of the electric wire 23 is pressed between the cross member 9 and the bulge 10 of the conductive busbar portion 4 by the force of the locking spring 3.

Figure 3 shows a perspective view of the drive arm 12 from the back side. It is clear that on the free, drive end 24 of the drive arm 12, which is located opposite the free, protruding end 15, the bearing shaft 13 is molded together with the lever arm 14. In this case, the bearing shaft 13 is located on the lower side of the lever arm 14 and has the already mentioned free space 17. The bearing shaft is so long that the support pins 25a, 25b protrude from the sides of the lever arm 14, which extend into the corresponding recesses under the bearing in the housing 2 from insulating material. On the upper side of the free space 17 there is a support 18 for abutting the locking spring 3 to the plate 16. The support 18 passes into a curved section 19, which slides along the plate 16 when the drive arm 12 is rotated.

Recesses 27 can be made in the support pins 25a, 25b, with which the drive arm 12 can be positioned without colliding, as close as possible to the locking spring 3, in order to save structural space.

Figure 4 shows once again a perspective view of the drive arm 12. It is clear that the bearing shaft 13 on the underside of the arm arm 14 is molded in one piece with the arm arm 14 of an insulating plastic material.

Figure 5 shows a perspective view of a connecting clamp with three spring-clamping connecting elements. It is seen that the electric wire 23 is inserted with its free end into the hole 11 for introducing the wire on the front side of the connecting clip 1. When the drive lever 12 is turned upward, the locking spring 3 is opened (compare with FIG. 2), so that the electric wire 23 can be inserted in the spring-clamping connecting element and there is clamped.

It is also seen that opposite the spring-clamping connecting elements with holes 11 for inputting wires, a plug-in region is provided for inserting a mating portion of the plug-in connector. A housing of insulating material for this is formed in this area with a corresponding guide and protective wall 21, which has a circuit suitable for the mating part of the plug connector.

Claims (12)

1. An electrical connection clamp (1) with a housing (2) of insulating material and with at least one spring-clamping element in the housing (2) of insulating material, the at least one spring-clamping element having a locking spring ( 3), which has a supporting arm (5) superimposed on the portion (4) of the conductive bus, a rear arc (6) of the spring adjacent to it, and a driving arm (7), and the driving arm (7) on the clamping section, bent in direction of the portion (4) of the conductive bus, has a recess (8) in the form of a window through which a portion (4) of the conductive busbar is passed and the lower cross member (9) of which forms a clamping point for clamping the electric wire (23) between the cross member (9) and the conductive bus section (4), and, moreover, the plate (16) protrudes from the drive arm (7) forward and outward in a direction opposite to the rear arc (6) of the spring, characterized in that each spring-clamping connecting element has a drive arm (12), which is rotatably located in front of the clamping portion of the drive arm (7) ) locking spring us (3) adjacent to the plate (16) and has a support (18) is oriented to be superposed on the plate (16). 2. An electrical connection clamp (1) according to claim 1, characterized in that the plate (16) extends along a common plane with a portion of the drive arm (7) extending in the direction of the arc (6) of the spring and adjacent to the plate (16), and the portion of the drive arm (7), provided with a recess (8) in the form of a window, is bent from this plane in the direction of the portion (4) of the conductive busbar. 3. An electrical connection clamp (1) according to claim 1 or 2, characterized in that the drive arm (12) with the support pins protruding on the sides (25a, 25b) is rotatably rotated in respective recesses for bearings in the housing (2) of insulating material. 4. An electrical connection clamp (1) according to claim 3, characterized in that the drive lever (12) is molded in one piece from plastic and has a lever arm (14) and a support shaft (13) partially covered from the lower side by a lever arm (14) in the region of the drive end (24) of the drive lever (12), wherein the shaft ends protruding beyond the side surfaces of the lever shoulder (14) form support trunnions (25a, 25b) protruding laterally, and in the support shaft (13) under the shoulder (14) of the lever there is free space (17) for receiving the plate (16) of the locking spring (3). 5. An electrical connection clamp (1) according to claim 4, characterized in that the support (18) for the plate (16) on the lower side of the drive arm (12) passes into a curved section (19) that extends from the free, drive end ( 24) the drive lever (12) to the upper side of the drive lever (12) adjacent to the free, drive end (24). 6. The electrical connecting clamp (1) according to claim 1 or 2, characterized in that it is made in the form of a plug connector with a plurality of spring-clamping connecting elements, each spring-clamping connecting element has its own current-carrying bus and current-carrying bus on the side opposite the hole (11) for the input of the wire in the housing (2) of insulating material leading to the corresponding connecting spring clip has a plug connector (20) for the counterpart of the plug connector or clamp for soldering printed circuit boards. 7. An electrical connection clamp (1) according to claim 6, characterized in that the drive arm (12) with the support pins protruding on the sides (25a, 25b) is rotatably rotated in respective recesses for bearings in the housing (2) of insulating material . 8. An electrical connection clamp (1) according to claim 7, characterized in that the drive arm (12) is molded in one piece from plastic and has a lever arm (14) and a support shaft (13) partially covered from the lower side by a lever arm (14) in the region of the drive end (24) of the drive lever (12), wherein the shaft ends protruding beyond the side surfaces of the lever shoulder (14) form support trunnions (25a, 25b) protruding laterally, and in the support shaft (13) under the shoulder (14) of the lever there is free space (17) for receiving the plate (16) of the locking spring (3). 9. An electrical connection clamp (1) according to claim 1 or 2, characterized in that it has a plurality of spring-clamping connecting elements, moreover, several spring-clamping connecting elements have a common current-carrying bus, on which sections (4) of the conductive bus for the spring are formed - clamping connecting elements. 10. An electrical connection clamp (1) according to claim 9, characterized in that the drive arm (12) with support pins protruding on the sides (25a, 25b) is rotatably rotated in respective recesses for bearings in the housing (2) of insulating material . 11. An electrical connection clamp (1) according to claim 10, characterized in that the drive arm (12) is molded in one piece from plastic and has a lever arm (14) and a support shaft (13) partially covered from the lower side by a lever arm (14) in the region of the drive end (24) of the drive lever (12), wherein the shaft ends protruding beyond the side surfaces of the lever shoulder (14) form support trunnions (25a, 25b) protruding laterally, and in the support shaft (13) under the shoulder (14) of the lever there is free space (17) for receiving the plate (16) of the locking spring (3). 12. An electrical connection clamp (1) according to claim 1 or 2, characterized in that the support (18) for the plate (16) on the lower side of the drive arm (12) passes into a curved section (19) that extends from the free, drive the end (24) of the drive arm (12) to the upper side of the drive arm (12) adjacent to the free, drive end (24).

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